Center/surface rewinder and winder

ABSTRACT

A winder for winding a web to produce a rolled product is provided. The winder includes a web transport apparatus that is used for conveying the web. Also included in one exemplary embodiment is a plurality of independent winding modules. The winding modules are independently positioned to independently engage the web as the web is conveyed by the web transport apparatus. The winding modules may be configured to wind the web to form a rolled product by center winding, surface winding, and combinations of center and surface winding. The winding modules are structurally and operationally independent of one another where if one module is disabled, another may still operate to produce the rolled product without shutting down the winder.

RELATED APPLICATIONS

The present application claims priority to and is a continuation-in-partapplication of U.S. patent application Ser. No. 11/930,977, filed onOct. 31, 2007, now U.S. Pat. No. 8,042,761 which is acontinuation-in-part application of U.S. patent application Ser. No.11/799,043, filed on Apr. 30, 2007, now U.S. Pat. No. 7,909,282 which isa continuation-in-part application of U.S. patent application Ser. No.10/085,813, filed on Feb. 28, 2002 now U.S. Pat. No. 8,210,462.

BACKGROUND

Winders are machines that roll lengths of paper, commonly known as paperwebs, into rolls. These machines are capable of rolling lengths of webinto rolls at high speeds through an automated process. Turret windersare well known in the art. Conventional turret winders comprise arotating turret assembly which support a plurality of mandrels forrotation about a turret axis. The mandrels travel in a circular path ata fixed distance from the turret axis. The mandrels engage hollow coresupon which a paper web can be wound. Typically, the paper web is unwoundfrom a parent roll in a continuous fashion, and the turret winderrewinds the paper web onto the cores supported on the mandrels toprovide individual, relatively small diameter logs. The rolled productlog is then cut to designated lengths into the final product. Finalproducts typically created by these machines and processes are toilettissue rolls, paper toweling rolls, paper rolls, and the like.

The winding technique used in turret winders is known as center winding.A center winding apparatus, for instance, is disclosed in U.S. Pat.Reissue No. 28,353 to Nystrand, which is incorporated herein byreference. In center winding, a mandrel is rotated in order to wind aweb into a roll/log, either with or without a core. Typically, the coreis mounted on a mandrel that rotates at high speeds at the beginning ofa winding cycle and then slows down as the size of the rolled productbeing wound increases, in order to maintain a constant surface speed,approximately matching web speed. Center winders work well when the webthat is being wound has a printed, textured, or slippery surface. Also,typically, center winders are preferable for efficiently producingsoft-wound, higher bulk rolled products.

A second type of winding is known in the art as surface winding. Amachine that uses the technique of surface winding is disclosed in U.S.Pat. No. 4,583,698. Typically, in surface winding, the web is wound ontothe core via contact and friction developed with rotating rollers. A nipis typically formed between two or more co-acting roller systems. Insurface winding, the core and the web that is wound around the core areusually driven by rotating rollers that operate at approximately thesame speed as the web speed. Surface winding is preferable forefficiently producing hard-wound, lower bulk rolled products.

A problem found in both center and surface winders involves the windershutting down when a condition such as a core load fault or a web breakfault occurs. If a core on a turret winder, for instance, is notproperly loaded onto the mandrel, the machine must shut down for thefault to be corrected. Similarly, a web break fault in a surface winderwill also result in shutting the machine down. This results in aproduction loss and the immediate requirement to obtain repair services.The present invention provides a way of eliminating such problems byallowing the machine to continue to produce rolled product even though afault condition has occurred. Additionally, the invention incorporatesthe advantages of both center and surface winding to produce rolledproducts having various characteristics by using either center winding,surface winding, or a combination of center and surface winding.

Another problem with both conventional center and surface winders isthat the winders provide limited control over the properties of theresulting rolled product. For instance, with respect to center winders,the only control mechanism for controlling the roll bulk of the finishedproduct is web tension. Thus, center winders can only produce productshaving a limited range of roll bulk without causing excessive delay orincreasing product strength to undesirable levels.

Surface winders are also similarly limited in the ability to control theroll bulk of resulting products. Surface winders, for instance, dependon surface friction to drive the winding roll. Attempts to produceproducts with a relatively high roll bulk require that the contactpressure between the material being wound and the surface winding devicebe decreased. Decreasing contact pressure, however, also decreasesfriction and results in loss of control over the product being formedleading to quality issues and productivity issues associated with loginstability in the winding pocket. Surface winders also have problemsrunning at relatively higher speeds when producing products with higherroll bulks.

In view of the above, a need currently exists for a system and processthat is capable of producing rolled products having a greater range ofroll bulk characteristics. In addition, a need exists for a system andprocess capable of producing products either having a low roll bulk or ahigh roll bulk while also producing the products at relatively highspeeds and without interruption.

In the prior art, a winder is typically known as an apparatus thatperforms the very first wind of that web, generally forming what isknown as a parent roll. A rewinder, on the other hand, is an apparatusthat winds the web from the parent roll onto a roll that is essentiallythe finished product. It is to be noted, the prior art is not consistentin designating what is and is not a winder or rewinder. For instance,rewinders are sometimes called winders, and winders are sometimesreferred to as rewinders.

SUMMARY

Objects and advantages of the invention will be set forth in part in thefollowing description, or may be obvious from the description, or may belearned from practice of the present invention.

As used herein, “winder” is generic to a machine for forming a parentroll, and a machine (rewinder) for forming a roll/log from a parentroll. In other words, the word “winder” is broad enough to cover both a“winder” and “rewinder”.

The present invention may include a web transport apparatus forconveying a web to a winder for winding the web to produce a rolledproduct. Also, a plurality of independent winding modules may bepresent. The winding modules are independently positioned toindependently engage the web as it is conveyed by the web transportapparatus. The winding modules engage the web and wind the web to form arolled product. The winding modules are configured to wind using centerwinding, surface winding, or a combination of center and surfacewinding. The winding modules are controlled and positioned independentof one another. Therefore, if one winding module is disabled anotherwinding module may still operate to produce the rolled product withouthaving to shut down the winder.

Also according to the present invention, a winder is disclosed as abovewhere the plurality of independent winding modules may each have a coreloading apparatus and a product stripping apparatus.

Also disclosed according to the present invention is a winder as setforth above where the plurality of independent winding modules each havea center driven mandrel onto which the web is wound to form the rolledproduct.

Also disclosed according to the present invention, is a method ofproducing a rolled product from a web. This method includes the step ofconveying the web by a web transport apparatus. Another step in themethod of the present invention may involve winding the web into therolled product by using one or more winding modules. This may involvewinding the web by one or more winding modules of the plurality ofwinding modules at any given time. The process that is used to wind theweb may be center winding, surface winding, or a combination of bothcenter and surface winding. The winding modules may act independently ofone another to allow one or more winding modules to still wind the webto produce a rolled product without having to shut down the plurality ofwinding modules if any of the remaining winding modules fault or aredisabled. The method according to the present invention also includesthe step of transporting the rolled product from the winding module.

Another exemplary embodiment of the present invention may include awinder that is used for winding a web to produce a rolled product thathas a web transport apparatus for conveying a web. This exemplaryembodiment also has a plurality of independent winding modules mountedwithin a frame where each winding module has a positioning apparatus formoving the winding module into engagement with the web. Each windingmodule also has a mandrel that is rotated onto which the web is wound toform the rolled product. The winding modules are operationallyindependent of one another where if any of the winding modules aredisabled, the remaining winding modules could continue to operate toproduce the rolled product without having to shut down the winder. Therotational speed of the mandrel and the distance between the mandrel andthe web transport apparatus may be controlled so as to produce a rolledproduct with desired characteristics. The winding modules are configuredto wind the web by center winding, surface winding, and combinations ofcenter and surface winding.

Another aspect of the present invention includes an exemplary embodimentof the winder as immediately discussed where each winding module mayhave a core loading apparatus for loading a core onto the mandrel. Thisexemplary embodiment also has a rolled product stripping apparatus forremoving the rolled product from the winding module.

For example, in one embodiment, the core loading apparatus may comprisea core loading assembly slidably mounted on a mandrel. The core loadingassembly may include a gripping device and a stabilizer. The grippingdevice can include at least two gripping members that are movabletowards and away from each other. For instance, the gripping members maybe pneumatically or hydraulically actuated. The stabilizer, on the otherhand, can be slidably engaged on the mandrel for stabilizing the mandrelas the gripping device pulls a core onto the mandrel. The stabilizer,for instance, may have a configuration similar to the gripping device.The stabilizer may include at least two stabilizing members that aremovable towards and away from each other and that surround the mandrel.Similar to the gripping device, the stabilizing members can bepneumatically or hydraulically actuated.

The core loading assembly can be attached to an actuator that isconfigured to move the core loading assembly back and forth across themandrel. In this embodiment, in order to load a core onto the mandrel,the gripping members of the gripping device engage a core at the firstend of the mandrel while the actuator moves the core loading assemblytowards the second end of the mandrel thereby pulling a core onto themandrel. The actuator, for instance, may comprise a linear track that ispowered by a servo motor.

In one embodiment, the gripping members have a shape that surrounds asubstantial portion of the core as it is pulled across the mandrel. Forinstance, the gripping members may define a rectangular-likecross-sectional shape that is configured to engage a core withoutharming the core.

In one embodiment, a controller, such as a microprocessor, may be placedin communication with the actuator and the core loading assembly. Thecontroller can be configured to load a core onto the mandrel accordingto a predetermined sequence for positioning the core at a particularlocation.

Once the core is loaded on the mandrel, a web of material is wound ontothe core to form a roll. In one embodiment, the core loading assemblycan be used also to push a formed roll off the mandrel.

Another aspect of the present disclosure is directed to an apparatus forbreaking a moving web while the web is being wound onto the mandrels. Inparticular, the apparatus for breaking the web is particularly wellsuited to breaking the web in order to form a new leading edge withouthaving to stop or slow down the web.

In one embodiment, for instance, the apparatus can include a firstrotating arm and a second rotating arm that are positioned adjacent to aconveying surface. The first rotating arm can be spaced upstream fromthe second rotating arm. The first rotating arm defines a first contactsurface that contacts the conveying surface when the arm is rotated andthe second rotating arm defines a second contact surface that alsocontacts the conveying surface when the arm is rotated.

In order to break a moving web on the conveying surface, both arms arerotated causing each of the contact surfaces to contact the moving webon the conveying surface simultaneously. The second rotating arm,however, is rotated at a faster speed than the first rotating arm duringcontact with the moving web causing the moving web to break in betweenthe first and second contact surfaces.

In one embodiment, for instance, a perforation line can be formed intothe moving web that is generally perpendicular to the direction ofmovement. The perforation line can be positioned in between the firstand second contact surfaces of the rotating arms during the breakingprocess causing the web to break along the perforation line.

The conveying surface in one embodiment can comprise a rotating rollthat rotates at generally the same speed as the web is moving. Forinstance, in one particular embodiment, the conveying surface maycomprise a vacuum roll that not only rotates but holds the web onto theconveying surface.

During the breaking process, the first contact surface can be moving atgenerally about the same speed as the moving web during contact. Thesecond contact surface, on the other hand, can be moving from about 2%to about 200% faster than the first contact surface. When the contactingsurfaces are simultaneously contacting the moving web, the contactingsurfaces can be spaced any suitable distance apart. For instance, in oneembodiment, the contact surfaces may be from about 2 inches to about 12inches apart, such as from about 4 inches to about 8 inches apart.

Yet another exemplary embodiment of the present invention includes awinder as substantially discussed above where each of the windingmodules has a center winding means, a surface winding means, and acombination center and surface winding means.

In one embodiment of a process and system made in accordance with thepresent disclosure, center and surface winding are used in combinationto control at least one property of the rolled product being formed. Inone embodiment, for instance, the process includes the steps ofunwinding a tissue web from a parent roll and conveying the tissue webdownstream on a web transport apparatus at a tension. A plurality ofwinding modules can be positioned adjacent to the web transportapparatus. Each winding module can include a mandrel that is inoperative association with a driving device. A rotating mandrel can bepositioned adjacent to the transport apparatus for forming a nip betweenthe web transport apparatus and the mandrel.

A tissue web can be conveyed into the nip formed between the mandrel andthe web transport apparatus so as to initiate winding of the web ontothe mandrel. In accordance with the present disclosure, the nippressure, the incoming tension, and/or the torque of the mandrel can becontrolled in order to control the roll bulk of a roll being wound. Inparticular, the above process is capable of producing rolled productshaving a wide range of roll bulk characteristics. For instance, nippressure, incoming tension and mandrel torque can all be controlled incombination to produce rolled products having a desired roll bulk ofanywhere between from about 2 cc/g to about 14 cc/g, such as from about3 cc/g to about 13 cc/g.

As described above, each winding module is capable of operatingindependently from another winding module in the system. In this manner,different winding modules can be configured to produce products havingthe same or different characteristics. For instance, in one embodiment,one winding module may be configured to produce products having acertain roll bulk while another winding module in the system may beconfigured to simultaneously produce products having a different rollbulk. In addition to different roll bulks, the different modules canalso produce products having different roll diameters.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of one exemplary embodiment of a winder ofthe present invention. This winder includes a plurality of independentwinding modules that are positioned in the web direction with respect toone another and substantially contained within a modular frame.

FIG. 2 is a perspective view of an exemplary embodiment of a winder ofthe present invention. This drawing shows a plurality of independentwinding modules, which are performing the various functions of a logwinding cycle.

FIG. 3 is a plan view of an exemplary embodiment of a winder of thepresent invention The drawing shows a plurality of independent windingmodules linearly situated with respect to one another and performing thevarious functions of a log winding cycle.

FIG. 4 is a front elevation view of an exemplary embodiment of a winderof the present invention. The drawing shows a plurality of independentwinding modules linearly situated with respect to one another andperforming the various functions of a log winding cycle.

FIG. 5 is a side elevation view of an exemplary embodiment of a winderof the present invention. The drawing shows winding modules in additionto other modules, which perform functions on a web.

FIG. 6 is a side elevation view of an exemplary embodiment of anindependent winding module in accordance with the present invention. Thedrawing shows the winding module engaging a web and forming a rolledproduct.

FIG. 7 is a side elevation view of an exemplary embodiment of a windingmodule in accordance with the present invention. The drawing shows thewinding module using rolls to form a rolled product via surface windingonly.

FIG. 8 is a side elevation of an exemplary embodiment of a winder inaccordance with the present invention. The drawing shows a plurality ofindependent winding modules being radially situated with respect to oneanother and interacting with a circular web transport apparatus.

FIG. 9 is a side elevation view of an exemplary embodiment of anindependent winding module in accordance with the present invention. Thedrawing shows a winding module that interacts with a circular webtransport apparatus.

FIG. 10 is a perspective view of a web being transported by a webtransport apparatus into proximity with a mandrel having a core.

FIG. 11 is a perspective view of a rotating mandrel and core that arewinding a web.

FIG. 12 is a perspective view of a rolled product with a core that isshown being stripped from a mandrel.

FIG. 13 is a perspective view of a mandrel that is in position to load acore.

FIG. 14 is a perspective view that shows a core being loaded onto amandrel via a core loading apparatus.

FIG. 15 is a side view of one embodiment of an apparatus for breaking amoving web.

FIGS. 16 through 23 are perspective views of an alternative embodimentof a core loading apparatus showing sequentially a core being loadedonto a mandrel and then being stripped from the mandrel.

FIG. 24 is a side view of the core loading assembly illustrated in FIGS.16 through 23.

DETAILED DESCRIPTION

Reference will now be made in detail to exemplary embodiments of theinvention, one or more examples of which are illustrated in thedrawings. Each example is provided by way of explanation of theinvention, and not meant as a limitation of the invention. For example,features illustrated or described as part of one exemplary embodimentcan be used with another exemplary embodiment to yield still a thirdexemplary embodiment. It is intended that the present invention includethese and other modifications and variations.

A winder is provided in the present invention that is capable of windingweb directly from a parent roll to form a rolled product. The winder maycomprise a winding module that has a rotating mandrel that engages theleading edge of a moving web. Upon transfer of the leading edge of theweb to the core, the winding mandrel is disengaged from the transportapparatus removing any nip pressure for the remainder of the wind. Theweb may be wound about the core through the rotation of the centerdriven mandrel. This type of winding is known as center winding.Additionally, the mandrel may be placed onto the web to form andmaintain nip pressure between the winding mandrel and the web. The webmay be wound about the core through the rotation of the surface drivenmandrel. This type of winding is a form of surface winding. As such, thewinding module of the present invention may wind web into a rolledproduct by center winding, surface winding, and combinations of centerand surface winding. This allows for the production of rolled productswith varying degrees of softness and firmness.

For example, in one embodiment, the winding apparatus may include adriven mandrel and a driven transport belt and the apparatus may includecontrol over the position of the mandrel, the drive control of themandrel, and the drive control of the transport belt in a manner thatcontrols web tension, nip forces and torque generation between thecenter drive and the surface drive to increase the product windingcapability. In this manner, for instance, the apparatus may be used toproduce products having relatively low roll bulks, products havingrelatively high roll bulks, and products having roll bulks anywhere inbetween. In addition, the improved control over winding conditions alsoallows for reduced perforation strengths when producing perforatedproducts. Of particular advantage, all of the above products can beproduced at relatively fast speeds, such as at speeds greater than 1500feet per minute, such as at speeds greater than 1800 feet per minute,such as even at speeds greater than 2000 feet per minute.

Also, the present invention provides for a winder that has a pluralityof independent winding modules. Each individual winding module may windthe web such that if one or more modules are disabled, the remainingmodules may continue to wind without interruption. This allows foroperator servicing and routine maintenance or repairs of a module to bemade without shutting down the winder. This configuration has particularadvantages in that waste is eliminated and efficiency and speed of theproduction of the rolled product is improved.

The present invention makes use of a winding module 12 as shown in FIG.1 in order to wind a web 36 and form a rolled product 22. Although aplurality of independent winding modules 12 may be used in the presentinvention to produce rolled products 22, the explanation of thefunctioning of only one winding module 12 is necessary in order tounderstand the building process of the rolled product 22.

Referring to FIG. 5, a web 36 is transported by a web transportapparatus 34 as shown. The web 36 is cut to a predetermined length byuse of, for instance, a cut-off module 60 may be configured as a pinchbar as is disclosed in U.S. Pat. No. 6,056,229. However, any othersuitable way to cut the web 36 to a desired length may be employed. Forexample, another embodiment of a cut-off module 60 made in accordancewith the present disclosure is shown in FIG. 15 which will be describedin more detail below. Additionally, the web 36 may be perforated by aperforation module 64 and have adhesive applied thereto by atransfer/tail seal adhesive applicator module 62 as also shown in FIG.5. Additionally, in other exemplary embodiments, adhesive may be appliedto the core 24 as opposed to the web 36. Referring back to FIG. 10, themandrel 26 is accelerated so that the speed of the mandrel 26 matchesthe speed of the web 36. Mandrel 26 has a core 24 located thereon. Themandrel 26 is lowered into a ready to wind position and awaits the web36. The core 24 is moved into contact with the leading edge of the web36. The web 36 is then wound onto core 24 and is attached to core 24 by,for instance, the adhesive previously applied or and by the contactbetween the core 24 and the web 36.

FIG. 11 shows the web 36 being wound onto the core 24. The winding ofthe web 36 onto core 24 may be controlled by the pressing of the core 24onto the web transport apparatus 34 to form a nip. The magnitude withwhich the core 24 is pressed onto the web transport apparatus 34 createsa nip pressure that can control the winding of the web 36 onto the core24. Additionally, the incoming tension of the web 36 can be controlledin order to effect the winding of the web 36 onto the core 24. Anothercontrol that is possible to wind the web 36 onto the core 24 involvesthe torque of the mandrel 26. Varying the torque on the mandrel 26 willcause a variance in the winding of the web 36 onto the core 24. Allthree of these types of winding controls, “nip, tension, and torquedifferential”, can be employed in the present invention. Also, thewinding of the web 36 may be affected by using simply one or two ofthese controls. The present invention therefore allows for anycombination of winding controls to be employed in order to wind the web36.

If not done before, the web 36 may be cut once the desired length of web36 has been rolled onto the core 24. At this point, the leading edge ofthe next web 36 will be moved by the web transport apparatus 34 intocontact with another winding module 12.

FIG. 12 shows the mandrel 26 being moved from a location immediatelyadjacent to the web transport apparatus 34 in FIG. 10 to a positionslightly above the web transport apparatus 34. The wound length of web36 is shown in FIG. 12 as being a rolled product 38 with a core 24. Now,a stripping function is carried out that moves the rolled product 38with a core 24 off of the mandrel 26. This mechanism is shown as aproduct stripping apparatus 28 in FIG. 2. The rolled product 38 with acore 24 is moved onto a rolled product transport apparatus 20 as shownin FIGS. 1 and 2.

Once the rolled product 38 with a core 24 is stripped from the mandrel26, the mandrel 26 is moved into a core loading position as shown inFIG. 13. The product stripping apparatus 28 is shown in more detail inFIG. 2. Once the product stripping apparatus 28 finishes stripping therolled product 38 with a core 24, the product stripping apparatus 28 islocated at the end of the mandrel 26. This location acts to stabilizethe mandrel 26 and prevent it from moving due to the cantileveredconfiguration of mandrel 26. In addition, the product strippingapparatus 28 helps to properly locate the end point of mandrel 26 forthe loading of a core 24.

FIG. 14 shows one embodiment of a core 24 being loaded onto the mandrel26. The loading of the core 24 is affected by a core loading apparatus32. The product stripping apparatus may also serve as a core loadingapparatus. The core loading apparatus 32 may be simply a frictionalengagement between the core loading apparatus 32 and the core 24.However, the core loading apparatus 32 can be configured in other waysknown in the art. For example, another embodiment of a core loadingapparatus made in accordance with the present disclosure is shown inFIGS. 16-24 which will be described in more detail below. In oneembodiment of the present invention, once the core 24 is loaded, acupping arm 70 (shown in FIG. 6) closes. Upon loading of the core 24onto the mandrel 26, the mandrel 26 is moved into the ready to windposition as shown in FIG. 10. The cores 24 are located in a coresupplying apparatus 18 as shown in FIGS. 1, 2, 3, and 4.

FIG. 1 shows an exemplary embodiment of a winder according to theinvention as a “rewinder” 10 with a plurality of independent windingmodules 12 arranged in a linear fashion with respect to one another. Aframe 14 supports the plurality of independent winding modules 12. A webtransport apparatus 34 is present which transports the web 36 foreventual contact with the plurality of independent winding modules 12.The frame 14 is composed of a plurality of posts 16 onto which theplurality of independent winding modules 12 are slidably engaged andsupported. The frame 14 may also be comprised of modular frame sectionsthat would engage each other to form a rigid structure. The number ofmodular frame sections would coincide with number of winding modulesutilized.

Situated adjacent to the frame 14 are a series of core supplyingapparatuses 18. A plurality of cores 24 may be included within each coresupplying apparatus 18. These cores 24 may be used by the plurality ofindependent winding modules 12 to form rolled products 22. Once formed,the rolled products 22 may be removed from the plurality of independentwinding modules 12 and placed onto a rolled product transport apparatus20. The rolled product transport apparatus 20 is located proximate tothe frame 14 and web transport apparatus 34.

FIG. 2 shows a rewinder 10 as substantially disclosed in FIG. 1 buthaving the frame 14 and other parts removed for clarity. In thisexemplary embodiment, the plurality of independent winding modules 12are composed of six winding modules 1-6. However, it is to be understoodthat the present invention includes exemplary embodiments having anynumber of independent winding modules 12 being other than six in number,for instance only one winding module 12 may be used in another exemplaryembodiment.

Each winding module 1-6 is shown performing a different function.Winding module 1 is shown in the process of loading a core 24 thereon.The plurality of independent winding modules 12 are provided with a coreloading apparatus for placing a core 24 onto a mandrel 26 of theplurality of independent winding modules 12. Any number of variations ofa core loading apparatus may be utilized in other exemplary embodimentsof the present invention. For instance, the core loading apparatus maybe a combination of a rod that extends into the core supplying apparatus18 and pushes a core 24 partially onto the mandrel 26 and a mechanismattached to the linear actuator of the product stripping apparatus 28that frictionally engages and pulls the core 24 the remaining distanceonto the mandrel 26. As shown in FIG. 2, winding module 1 is in theprocess of pulling a core 24 from the core supplying apparatus 18 andplacing the core 24 on mandrel 26.

Referring to FIGS. 16-24, one embodiment of a core loading apparatusthat may be used in accordance with the present disclosure is shown. Inparticular, FIGS. 16-23 illustrate a sequence of loading a core 24 ontoa mandrel 26 in order to form a rolled product 22 which is then strippedoff the mandrel 26.

As shown in FIG. 16, the core loading apparatus includes a core loadingassembly 200 that slides back and forth across the mandrel 26. The coreloading assembly 200 includes a gripping device 202 for engaging thecore 24 and optionally a stabilizer 204. The core loading assembly 200is attached to an actuator 208, such as a linear actuator as shown. Inparticular, the core loading assembly 200 is mounted to the linearactuator which is positioned parallel to the mandrel 26. The actuator208 includes a motor 210 that drives a track 212. The track 212 isattached to the core loading assembly 200 such that the core loadingassembly traverses back and forth across the mandrel 26 as the motor 206drives the track 212. The track 212 may comprise, for instance, a beltas shown or can be a chain or any other suitable device.

In addition to the linear actuator 208 as shown in FIG. 16, it should beunderstood that any suitable actuator may be used that is capable ofmoving the core loading assembly 200 along the mandrel 26. For example,in other embodiments, a pneumatic or hydraulic actuator may be used.Alternatively, a ball screw or the like may be used as the actuator.

The mandrel 26 as shown is supported on one end by a bearing 214. On theopposite end, the mandrel 26 is engagable with a cupping arm 70. Thecupping arm 70 is in communication with a motor 206. The motor 206causes the cupping arm to rotate thereby engaging and disengaging theend of the mandrel 26. For example, in FIG. 20, the cupping arm 70 isshown in the engaged position for supporting the end of the mandrel 26.The cupping arm 70 is used to engage and support the end of the mandrel26 during winding. When loading the core 24 or when stripping a rolledproduct from the mandrel 26, on the other hand, the cupping arm 70disengages the mandrel 26. When the cupping arm 70 is disengaged fromthe mandrel 26, the stabilizer 204 of the core loading assembly engagesthe mandrel for supporting the mandrel while a core is being loaded.

As illustrated in FIG. 16, the gripping device 202 and the stabilizer204 are contained within a housing 216 to form the core loading assembly200. An enlarged view of the gripping device 202 and the stabilizer 204with the housing removed is shown in FIG. 18. A cross-sectional view ofthe gripping device 202 is also illustrated in FIG. 24. As shown in FIG.24, the gripping device 202 includes gripping members 218 that areintended to surround and grip the core 24. In the embodiment illustratedin FIG. 24, four gripping members 218 are shown. It should beunderstood, however, that a greater or lesser number of gripping membersmay be utilized. The gripping members are movable towards and away fromeach other for gripping and releasing the core 24.

For example, in one embodiment, the gripping members 218 can bepneumatically or hydraulically actuated. In this regard, as shown inFIG. 18, the gripping device 202 includes a fluid inlet 220 and a fluidoutlet 222. The fluid inlet 220 and the fluid outlet 222 are for flowinga fluid into and out of the gripping device 202 for respectively movingthe gripping members 218 towards and away from each other.

In the embodiment illustrated in FIG. 24, the gripping members 218generally form a rectangular-like cross-sectional shape for engaging thecore 24. It should be understood, however, that any suitablecross-sectional shape capable of surrounding the core 24 for engagingthe core can be utilized. For example, in an alternative embodiment, thegripping device 202 may only include two gripping members that have anarc-like shape.

The gripping members 218 of the gripping device 202 are intended toengage and hold the core 24 for pulling the core onto the mandrel 26without damaging the core. For example, having the gripping members 218be fluid controlled allows for fine adjustments in the amount ofpressure being placed on the core 24. In addition, the gripping members218 can pivot which allows for the gripping members to accommodate forsome misalignment.

For instance, as shown in FIG. 24, the gripping device 202 includes afirst pivot member 223 defining a first pivot point 224 and a secondpivot member 225 defining a second pivot point 226. In addition, thegripping device 202 includes four springs 228. More particularly, thepivot point 224 is surrounded by an upper and lower spring 228, whilethe pivot point 226 is also surrounded by an upper and lower spring 228.The pivot points and the springs allow the pivot members 223 and 225 andthus the gripping members 218 some flexibility in movement. Moreparticularly, the right pair of gripping members 218 can pivot about thepivot point 224 while the left pair of gripping members 218 can pivotabout the pivot point 226. In this manner, when the core 24 is engagedby the gripping members, not only can the gripping members move back andforth but can also pivot for pulling the core onto the mandrel withoutmisalignment and without damaging the core.

The gripping members 218 can be made from any suitable material capableof engaging the core 24 without damaging the core. The gripping members218, for instance, can be made for any suitable hard or soft material.In one particular embodiment, for instance, the gripping members 218 canbe made from a metal.

As shown in FIG. 18, the core loading assembly 200 also includes thestabilizer 204. The stabilizer 204 can be included in the assembly inorder to stabilize the mandrel as the core is being loaded onto themandrel. In one embodiment, as shown in FIG. 18, the stabilizer 204 cangenerally have the same construction as the gripping device 202. Forinstance, the stabilizer 204 can include at least two stabilizingmembers that slidably engage the mandrel 26 and move towards and awayfrom each other by flowing a fluid through a fluid inlet 230 and a fluidoutlet 232. In one embodiment, the stabilizer 204 can include fourstabilizing members having the same exact configuration as the grippingmembers 218. The stabilizing members, however, are for slidably engagingthe mandrel 26. In this regard, the stabilizing members can have a lowfriction surface made from a lubricating material, such as a polyolefin.The stabilizing members, for instance, can include a polyethylene or apolypropylene surface that slides among the mandrel 26 as the core 24 isloaded.

The core loading assembly 200 and the actuator 208 can be placed incommunication with a controller, such as a microprocessor that iscapable of actuating a sequence for loading a core onto the mandrel at adesired position and then stripping a rolled product from the mandrel.One sequence for loading a core onto the mandrel is illustrated in FIGS.16-23.

For instance, as shown in FIG. 16, in order to load the core 24 onto themandrel 26, the cupping arm 70 is first disengaged from the mandrel 26and the core loading assembly 200 is positioned at the open end of themandrel 26. In this manner, not only is the core loading assembly 200 ata position for engaging the core 24 but also stabilizes the mandrel 26when the cupping arm 70 is disengaged.

As shown in FIGS. 17 and 18, the gripping device 202 surrounds an outercircumference of the core 24 for engaging the core. The core can besupplied to the gripping device from a core supplying apparatus.

Once the core is engaged, the core 24 is pulled onto the mandrel 26 asshown in FIG. 19 using the actuator 208. The actuator 208 can beconfigured to place the core 24 at a particular position on the mandrel26. Once the core 24 is positioned into a particular position, thegripping device 202 can release the core as shown in FIG. 20. The coreloading assembly 200 is then moved further to the end of the mandrel toprevent interference with the core 24 as a web of material is wound ontothe core. Also, as shown in FIG. 20, the cupping arm 70 is moved backinto engagement with the mandrel 26.

Once the core 24 is loaded onto the mandrel 26 as shown in FIG. 20, arolled product 22 is formed on the mandrel as shown in FIG. 21. Ofparticular advantage, in this embodiment, the core loading assembly 200can also be used to strip the rolled product 22 from the mandrel 26. Forinstance, as shown in FIG. 22, once the rolled product 22 is formed, theactuator 208 can move the core loading assembly 200 into engagement withthe rolled product for sliding the rolled product off the mandrel 26 asshown in FIG. 23. The rolled product 22 once stripped from the mandrel26 can then be fed to a rolled product transfer apparatus. Of particularadvantage, the core loading assembly 200 stabilizes the mandrel as itpushes the rolled product off of the mandrel. In particular, the coreloading assembly 200 holds the open free end of the mandrel whichreduces the whip of the mandrel and therefore prevents againstmisalignments. Further, once the rolled product is stripped from themandrel, the core loading assembly 200 is in a position for engaging andpulling a new core onto the mandrel.

The core loading apparatus described above can provide various benefitsand advantages when forming the rolled products. For example, the coreloading apparatus as described above is capable of pulling the coresonto the mandrel into a fixed position. In addition, the mandrel isstabilized and held in position during the loading process. Byminimizing positional changes of the core and of the mandrel, thelikelihood of successful core loading is vastly improved, whichmaximizes productivity and minimizes waste with respect to core loadingoperations. Furthermore, the core loading apparatus as described aboveis conducive to various conditions of core material and rigidity. Forexample, limp or flaccid cores can be pulled onto mandrels instead ofrigid paper material if desired. In addition, the core loading apparatusalso serves as a log strip device after the rolled product is formed.This dual function is advantageous because it simplifies design andminimizes hardware.

Referring back to FIG. 2, winding module 2 is shown as having removedthe rolled product 22 from its mandrel 26. The rolled product 22 isplaced onto a rolled product transport apparatus 20. In this case, therolled product 22 is a rolled product with a core 38. Such a rolledproduct with a core 38 is a rolled product 22 that is formed by havingthe web 36 being spirally wrapped around a core 24. It is to beunderstood that the rolled product 22 may also be a rolled product thatdoes not have a core 24 and instead is simply a solid roll of wound web36. It may also be the case that the rolled product 22 formed by thepresent invention does not include a core 24, but has a cavity in thecenter of the rolled product 22. Various configurations of rolledproduct 22 may thus be formed in accordance with the present invention.

Each of the plurality of independent winding modules 12 is provided witha product stripping apparatus 28 that is used to remove the rolledproduct 22 from the winding modules 1-6. Winding module 3 is shown asbeing in the process of stripping a rolled product 22 from the windingmodule 3. The product stripping apparatus 28 is shown as being a flangewhich stabilizes the mandrel 26 and contacts an end of the rolledproduct 22 and pushes the rolled product 22 off of the mandrel 26. Also,the product stripping apparatus 28 helps locate the end of the mandrel26 in the proper position for the loading of a core 24. The rolledproduct stripping apparatus 28 therefore is a mechanical apparatus thatmoves in the direction of the rolled product transport apparatus 20. Theproduct stripping apparatus 28 may be configured differently in otherexemplary embodiments of the invention.

The winding module 4 is shown as being in the process of winding the web36 in order to form the rolled product 22. This winding process may becenter winding, surface winding, or a combination of center and surfacewinding. These processes will be explained in greater detail below.

Winding module 5 is shown in a position where it is ready to wind theweb 36 once the winding module 4 finishes winding the web 36 to producea rolled product 22. In other words, winding module 5 is in a “ready towind” position.

Winding module 6 is shown in FIG. 1 in a “racked out” position. It maybe the case that winding module 6 has either faulted or is in need ofroutine maintenance and is therefore moved substantially out of frame 14for access by maintenance or operations personnel. As such, windingmodule 6 is not in a position to wind the web 36 to produce rolledproduct 22, but the other five winding modules 1-5 are still able tofunction without interruption to produce the rolled product 22. Byacting as individual winders, the plurality of independent windingmodules 12 allow for uninterrupted production even when one or more ofthe winding modules becomes disabled.

Each winding module 12 may have a positioning apparatus 56 (FIG. 4). Thepositioning apparatus 56 moves the winding module perpendicularly withrespect to web transport apparatus 34, and in and out of engagement withweb 36. Although the modules 12 are shown as being moved in asubstantially vertical direction, other exemplary embodiments of theinvention may have the modules 12 moved horizontally or even rotatedinto position with respect to web 36. Other ways of positioning themodules 12 can be envisioned.

Therefore, each of the plurality of independent winding modules 12 maybe a self-contained unit and may perform the functions as described withrespect to the winding modules 1-6. Winding module 1 may load a core 24onto the mandrel 26 if a core 24 is desired for the particular rolledproduct 22 being produced. Next, the winding module 1 may be linearlypositioned so as to be in a “ready to wind” position. Further, themandrel 26 may be rotated to a desired rotational speed and thenpositioned by the positioning apparatus 56 in order to initiate contactwith the web 36. The rotational speed of the mandrel 26 and the positionof the winding module 1 with respect to the web 36 may be controlledduring the building of the rolled product 22. After completion of thewind, the position of the module 1 with respect to the web 36 will bevaried so that the winding module 1 is in a position to effect removalof the rolled product 22. The rolled product 22 may be removed by theproduct stripping apparatus 28 such that the rolled product 22 is placedon the rolled product transport apparatus 20. Finally, the windingmodule 1 may be positioned such that it is capable of loading a core 24onto the mandrel 26 if so desired. Again, if a coreless rolled productwere to be produced as the rolled product 22, the step of loading a core24 would be skipped. It is to be understood that other exemplaryembodiments of the present invention may have the core 24 loadingoperation and the core 24 stripping operation occur in the same ordifferent positions with regard to the mandrel 26.

The rewinder 10 of the present invention may form rolled products 22that have varying characteristics by changing the type of windingprocess being utilized. The driven mandrel 26 allows for center windingof the web 36 in order to produce a low density, softer rolled product22. The positioning apparatus 56 in combination with the web transportapparatus 34 allow for surface winding of the web 36 and the productionof a high density, harder wound rolled product 22. Surface winding isinduced by the contact between the core 24 and the web 36 to form a nip68 (shown in FIG. 6) between the core 24 and the web transport apparatus34. Once started, the nip 68 will be formed between the rolled product22 as it is built and the web transport apparatus 34. As can be seen,the rewinder 10 of the present invention therefore allows for bothcenter winding and surface winding in order to produce rolled products22. In addition, a combination of center winding and surface winding maybe utilized in order to produce a rolled product 22 having varyingcharacteristics. For instance, winding of the web 36 may be affected inpart by rotation of the mandrel 26 (center winding) and in part by nippressure applied by the positioning apparatus 56 onto the web 36(surface winding). Therefore, the rewinder 10 may include an exemplaryembodiment that allows for center winding, surface winding, and anycombination in between. Additionally, as an option to using a motor tocontrol the mandrel speed/torque a braking device (not shown) on thewinding modules 12 may be present in order to further control thesurface and center winding procedures.

The plurality of independent winding modules 12 may be adjusted in orderto accommodate for the building of the rolled product 22. For instance,if surface winding were desired, the pressure between the rolled product22 as it is being built and the web transport apparatus 34 may beadjusted by the use of the positioning apparatus 56 during the buildingof the rolled product 22.

In addition to controlling the torque of the mandrel and the nippressure as described above, web tension can also be controlled duringthe process. Web tension can be controlled in various ways. Web tensioncan be controlled, for instance, by varying a draw of the tissue webbetween the mandrel and a tension device upstream. The tension deviceupstream, for instance, may comprise the device that unwinds the parentroll or may comprise another web tension device positioned prior to theweb transport apparatus. In one embodiment, for instance, a suctiondevice, such as a vacuum roll, may be positioned in the system prior tothe web transport apparatus 34. Web tension can then be controlled byvarying the draw between the mandrel and the vacuum roll or by varyingthe draw between the mandrel and the web transport apparatus combinedand the vacuum roll.

Instead of or in addition to the above, web tension can also becontrolled in various other ways. For instance, web tension can also becontrolled by controlling the mandrel speed in relation to the amount offorce being exerted on the tissue web by the web transport apparatus.

Utilizing a plurality of independent winding modules 12 allows for arewinder 10 that is capable of simultaneously producing rolled product22 having varying attributes. For instance, the rolled products 22 thatare produced may be made such that they have different sheet counts.Also, the rewinder 10 can be run at both high and low cycle rates withthe modules 12 being set up in the most efficient manner for the rolledproduct 22 being built. The winding modules 12 of the present inventionmay have winding controls specific to each module 12, with a commonmachine control. Real time changes may be made where different types ofrolled products 22 are produced without having to significantly modifyor stop the rewinder 10. Real time roll attributes can be measured andcontrolled. The present invention includes exemplary embodiments thatare not limited to the cycle rate.

The present invention is also capable of producing a wide spectrum ofrolled products 22, and is not limited towards a specific width of theweb 36.

In one particular embodiment, the present disclosure is particularlydirected to a system that is capable of producing products having anydesired roll bulk within a relatively large roll bulk range. The rollbulk of the resulting product, for instance, can be controlled bycontrolling at least one of the nip pressure, the incoming tension ofthe tissue web and/or the torque of the mandrel as described above. Inone embodiment, for instance, only a single one of the above processconditions can be controlled to vary roll bulk, such as the nippressure. In another embodiment, at least two of the above processconditions can be controlled to produce products. In still anotherembodiment, all three of the above process conditions can be controlledtogether to produce a product having a desired roll bulk. For example,softer rolls having relatively high roll bulk levels can be created bydecreasing the torque of the mandrel, decreasing the nip pressurebetween the mandrel and the transport conveyor and/or decreasingincoming tension, which may be the tension between the mandrel and atension device upstream, such as a vacuum roll. Conversely, more firmrolls having less roll bulk can be made by increasing the torque of themandrel, increasing nip pressure, and/or increasing incoming tension.

The system of the present disclosure, for instance, is capable ofproducing rolled products having a roll bulk anywhere between from about2 cc/g to about 14 cc/g, such as from about 3 cc/g to about 13 cc/g.Conventional rewinders, such as surface driven winders or center drivenwinders, on the other hand, simply are not capable of producing productswithin such a broad range of roll bulks efficiently or at consistentlyhigh production speeds.

Of particular advantage, products can be made within the entire rollbulk range described above without having to substantially reduce thespeed of the system. In particular, products having any desired rollbulk can be produced while the tissue web is traveling at a speed ofgreater than about 1500 feet/minute, such as greater than about 1800feet/minute, such as greater than 2000 feet/minute. In one embodiment,for instance, the products can be produced while the tissue web ismoving at a speed of from about 2000 feet/minute to about 3000feet/minute, such as even greater than 2500 feet/minute.

In one particular embodiment, the system of the present invention isused to produce products having a relatively high roll bulk, such asproducts having a roll bulk of greater than about 8 cc/g, such as evengreater than 10 cc/g. In producing products having a relatively highroll bulk, one of the advantages of the system of the present disclosureis that the tissue web can be fed to the mandrel at a web tension ofsubstantially zero. In addition, once the product is produced on themandrel, the tissue sheet can be cut at very low web tension, especiallywhen using the cut-off module 60 as shown in FIG. 15. In particular, thetissue web can be cut at a detach strength of less than about 220 gramsof force, such as less than about 200 grams of force, such as less thanabout 190 grams of force, such as even less than about 180 grams offorce at a rollwidth of 4.2 inches.

The plurality of independent winding modules 12 can be designed in sucha way that maintenance may be performed on any one or more of thewinding modules 1-6 without having to interrupt operation, as previouslydiscussed with winding module 6. A winding module 12 may be removed andworked on while the rest keep running. Further, having a plurality ofindependent winding modules 12 allows for an increase in the timeintervals available for the core 24 loading functions and the rolledproduct 22 stripping functions. Allowing for an increase in these timeintervals greatly reduces the occurrence of loading and strippingerrors. Also, prior art apparatuses experiencing interruption of thewinding operation will produce a rolled product 22 that is not complete.This waste along with the waste created by the changing of a parent rollor product format change will be reduced as a result of the rewinder 10in accordance with the present invention. Waste may be removed from therewinder 10 by use of a waste removal apparatus 200 (FIG. 5) as is knownin the art.

FIG. 3 shows a rewinder 10 having a frame 14 disposed about a pluralityof independent winding modules 12. The frame 14 has a plurality of crossmembers 42 transversing the ends of the frame 14. The positioningapparatus 56 that communicates with the winding modules 1-6 is engagedon one end to the cross members 42, as shown in FIG. 4. A verticallinear support member 44 is present on the plurality of independentwinding modules 12 in order to provide an attachment mechanism for thepositioning apparatus 56 and to provide for stability of the windingmodules. The positioning apparatus 56 may be a driven roller screwactuator. However, other means of positioning the plurality ofindependent winding modules 12 may be utilized. The vertical supportmembers 44 also may engage a vertical linear slide support 58 that isattached to posts 16 on frame 14. Such a connection may be of variousconfigurations, for instance a linear bearing or a sliding railconnection. Such a connection is shown as a vertical linear slide 52that rides within the vertical linear slide support 58 in FIG. 4.

A horizontal linear support member 46 is also present in the pluralityof independent winding modules 12. The horizontal linear support member46 may communicate with a horizontal linear slide 54 (as shown in FIG.6) to allow some or all of the plurality of independent winding modules12 to be moved outside of the frame 14. The horizontal linear slide 54may be a linear rail type connection. However, various configurationsare envisioned under the present invention.

FIG. 6 shows a close up view of an exemplary embodiment of a windingmodule in accordance with the present invention. The servomotor 50 canbe supported by the module frame 48 onto which a mandrel cupping arm 70is configured. The mandrel cupping arm 70 is used to engage and supportthe end of the mandrel 26 opposite the drive during winding. As can beseen, the positioning apparatus 56 may move the winding module forengagement onto the web 36 as the web 36 is transported by the webtransport apparatus 34. Doing so will produce a nip 68 at the point ofcontact between the mandrel 26 and the transport apparatus 34, with theweb 36 thereafter being wound onto the mandrel 26 to produce a rolledproduct 22.

FIG. 7 shows another exemplary embodiment of a winder module inaccordance with the present invention. The exemplary embodiment in FIG.7 is substantially similar to the exemplary embodiment shown in FIG. 6with the exception of having the winding process being a pure surfaceprocedure. A drum roll 72 is located at approximately the same locationas the mandrel 26 of FIG. 6. In addition, the exemplary embodiment shownin FIG. 7 also has another drum roll 74 along with a vacuum roll 76. Inoperation, the web 36 is conveyed by the web transport apparatus 34 inthe direction of arrow A. The web transport apparatus 34 may be a vacuumconveyor or a vacuum roll. However, it is to be understood that avariety of web transport apparatus 34 may be utilized, and the presentinvention is not limited to one specific type. Another exemplaryembodiment of the present invention employs a web transport apparatus 34that is an electrostatic belt that uses an electrostatic charge to keepthe web 36 on the belt. The vacuum roll 76 draws the web 36 from the webtransport apparatus 34 and pulls it against the vacuum roll 76. The web36 is then rotated around the vacuum roll 76 until it reaches a locationapproximately equal distance from the drum roll 72, drum roll 74, andvacuum roll 76. At such time, the web 36 is no longer pulled by thevacuum in the vacuum roll 76 and is thus able to be rolled into a rolledproduct 22 by way of surface winding by the drum roll 72, drum roll 74,and vacuum roll 76. The rolled product 22 that is formed in theexemplary embodiment shown in FIG. 7 is a coreless rolled productwithout a cavity 78. The winding module may also be modified such thatmore than or fewer than three rolls are used to achieve the surfacewinding process. Further, the production of the rolled product 22 havinga core 24 or a coreless cavity in the rolled product 22 can be achievedin other exemplary embodiments using a similar configuration as shown inFIG. 7.

The plurality of winding modules 12 may also be modified such thatadditional improvements are realized. For instance, a tail sealingapparatus 30 may be included on the plurality of independent windingmodules 12. As shown in FIG. 2, the tail sealing apparatus 30 is locatedon the underside of the plate 48. The tail sealing apparatus 30 may be aseries of holes from which an adhesive is sprayed onto the rolledproduct 22 as the final lengths of the web 36 are rolled onto the rolledproduct 22. The adhesive causes the tailing end of the web 36 to beadhered to the rolled product 22. It is therefore possible to seal thetail of the rolled product 22 before being unloaded to the rolledproduct transport apparatus 20. Of course, it may also be possible toprovide adhesive to the web 36 at a point other than at the plurality ofindependent winding modules 12. As stated, for example, adhesive may beapplied by the tail sealing module 62 as shown in FIG. 5. Also, it mayalso be the case that sealing of the tail of the web 36 onto the rolledproduct 22 may be done offline, beyond the winder.

In order to get the web 36 onto the mandrel 26, the mandrel 26 as shownin FIG. 6, may be a vacuum supplied mandrel. Such a vacuum mandrel 26will pull the web 36 onto the mandrel 26 by means of a vacuum suppliedthrough all or parts of the vacuum mandrel 26. Other ways of assistingthe transfer of the web 36 onto the mandrel 26 are also possible. Forinstance, an air blast may be provided under the surface of the webtransport apparatus 34 or a taming apparatus may be placed under the webtransport apparatus 34 to propel the web 36 into contact with themandrel 26. Further, the positioning apparatus 56 may be used to pushthe winding module down onto the web 36 to effect the winding. Again,the rewinder 10 of the present invention is thus capable of producing arolled product 22 which has a core, which is solid without a core orcavity therethrough, or which does not have a core but does have acavity therethrough. Such a rolled product 22 that is produced without acore 24, yet having a cavity therethrough could be produced by using avacuum supplied mandrel 26.

FIG. 5 shows an exemplary embodiment of a rewinder 10 that makes use ofseveral modules upstream from the plurality of independent windingmodules 12. For instance, a cut-off module 60 is utilized that seversthe web 36 once a desired amount of web 36 is transported for theproduction of a rolled product 22. This severing creates a new leadingedge for the next available winding module 1-6 to engage. However, it isto be understood that a cut-off module 60 may be utilized at locationsimmediately adjacent to or at the nip 68 of the plurality of independentwinding modules 12. Also, FIG. 5 shows an adhesive application module 62on the web transport apparatus 34. This adhesive application module 62may be an apparatus for applying adhesive or an adhesive tape onto theweb 36 in such a fashion that the adhesive would be applied to the tailend of the rolled product 22 sheet. The adhesive application module 62may apply adhesive to the web 36 so that both the rolled product 22 willbe sealed upon completion and the leading edge of the web 36 will have asource of adhesion to transfer to the core of the next successivemodule. A perforation module 64 is also provided in order to perforatethe web 36 such that individual sheets may be more easily removedtherefrom.

One particular embodiment of a cut-off module 60 that is particularlywell suited to breaking the web 36 while moving is shown in FIG. 15. Inparticular, the cut-off module 60 as illustrated in FIG. 15 can form abreak in the web 36 without having to stop or decelerate the web duringthe winding process.

As shown, the cut-off module 60 includes a rotating roll 300, such as avacuum roll that rotates with the web 36 and defines a conveying surface302. In this embodiment, the vacuum roll 300 is placed adjacent to aguide roll 304 which can receive the web 36 from a parent roll ordirectly from a papermaking process. Not shown is a perforation module64. The web 36, however, can be perforated as it is unwound or can bepre-perforated.

As shown in FIG. 15, the cut-off module 60 includes a first rotating arm306 spaced upstream from a second rotating arm 308. The first rotatingarm 306 defines a first contact surface 310 while the second rotatingarm 308 defines a second contact surface 312. As shown, the contactsurfaces 310 and 312 simultaneously contact the moving web 36 while onthe conveying surface 302 when the arms are rotated. In order to rotatethe arms 306 and 308, the arms can be mounted onto a bearing and drivenby any suitable driving device, such as a motor.

In the embodiment illustrated in FIG. 15, the rotating arms 306 and 308are shown in an engagement position for breaking the moving web 36 andforming a new leading edge. When the web 36 is being fed into theprocess, the arms 306 and 308 can be rotated so as to not interfere withthe unwinding of the web from the parent roll 304. In particular, thearms 306 and 308 in one embodiment may have a rest position just out ofengagement clockwise with the moving web.

When it is desirable to form a break in the web, however, each of thearms 306 and 308 can be rotationally accelerated so that both contactsurfaces 310 and 312 contact the moving web on the conveying surface 302simultaneously. In order for the web to break, however, the secondrotating arm 308 is rotated slightly faster than the first rotating arm306. In this manner, the first rotating arm 306 serves to hold the webagainst the conveying surface while the second arm 308 pulls and breaksthe web. In one embodiment, the arms are spaced a distance and theprocess is timed so that both contact surfaces 310 and 312 contact theweb 36 when there is a perforation line located in between the twocontact surfaces. In this manner, the break occurs along the perforationline.

More particularly, in order to form a break in the web, the first arm306 is accelerated to a speed such that the contact surface 310 contactsthe web 36 at a speed that is either slower or at substantially the samespeed at which the web is moving.

As described above, the second arm 308 is rotated at a speed such thatthe contact surface 312 contacts the moving web at a speed greater thanat which the first contact surface 310 is moving. For instance, in oneembodiment, the second contact surface 312 can be moving at a speed thatis from about 2% to about 200% faster than the speed at which the firstcontact surface 310 is moving. For example, in one particularembodiment, the second contact surface 312 can be moving at a speed thatis from about 5% to about 30% faster than the speed at which the firstcontact surface 310 is moving when contact with the web occurs.

The contact surface 312 of the second arm 308, for instance, can betraveling at a speed that is substantially the same speed at which theweb is moving when the speed of the first contact surface 310 is slowerthan the speed of the web. Alternatively, the second contact surface 312may be moving at a speed faster than that at which the web is moving.

When the contact surfaces 310 and 312 contact the moving web, in oneembodiment, the first contact surface 310 contacts the web prior to thesecond contact surface 312. Both contact surfaces 310 and 312, however,are generally both in contact with the web as the web is being broken.During the breaking process, the first contact surface 310 holds the webfor a brief moment of time while the second contact surface 312 pulls onthe web with sufficient force for the break to occur.

The spacing between the first arm 306 and the second arm 308 duringcontact with the web can vary greatly depending upon the particular typeof web material being conveyed and various other factors. For instance,in one embodiment, the contact surfaces 310 and 312 can be spaced fromabout 1 inch to about 20 inches apart. When processing bath tissue, thecontact surfaces, for instance, can be spaced from about 2 inches toabout 12 inches apart, such as from about 4 inches to about 8 inchesapart, during contact with the web. The spacing, for instance, can beset so that the arms do not interfere with each other and allows foraccuracy in placing a perforation line in between the two contactsurfaces.

The contact surfaces 310 and 312 can be made from the same material orfrom different materials. In one embodiment, for instance, the secondcontact surface 312 can have a higher coefficient of friction than thefirst contact surface 310. For instance, the second contact surface 312can be made from a rubber-like material that better grips the web duringthe breaking process. The first contact surface 310, on the other hand,can be a low friction material that prevents interference with themoving web. For instance, in one embodiment, the first contact material310 can be made from a textile material, such as a loop material.

The cut-off module 60 as shown in FIG. 15 can provide various advantagesand benefits. For instance, by using two contact surfaces 310 and 312,the web 36 can be efficiently and effectively broken and severed over awide range of web properties and processing conditions. In addition, thetwo rotating arms as described above place tension only on a shortlength of the web 36 during the break. In particular, the web is onlyunder tension in between the two contact points of the arms whichprevents the moving web from wrinkling, folding or otherwise falling outof misalignment. The cut-off module also provides web control upstreamand downstream from the cut-off edge, which minimizes slack in the webin the winding roll that is being finished as well as in the leadingportion of the new web for the new roll to be wound. The apparatus alsoprevents the web from sliding upstream and enables a robust break athigh or low speed and at high or low web tension.

Also shown in FIG. 5 is a waste removal apparatus 200 for removing extraweb 36 that results from faults such, as web breaks, and machine startups. This waste is moved to the end of the web transfer apparatus 34 andthen removed. The use of a plurality of individual modules 12 reducesthe amount of waste because once a fault is detected, the affectedmodule 12 is shut down before the rolled product is completely wound.The web is severed on the fly and a new leading edge is transferred tothe next available module. Any waste is moved to the end of the webtransfer apparatus 34 and then removed.

It is believed that using a web transport apparatus 34 that has a vacuumconveyor or a vacuum roll will aid in damping the mandrel 26 vibrationsthat occur during transfer of the web 36 onto the mandrel and alsoduring the winding of the mandrel 26 to form a rolled product 22. Doingso will allow for higher machine speeds and hence improve the output ofthe rewinder 10.

Each of the winder modules 1-6 of the plurality of independent windingmodules 12 do not rely on the successful operation of any of the othermodules 1-6. This allows the rewinder 10 to operate whenever commonlyoccurring problems during the winding process arise. Such problems couldinclude for instance web breaks, ballooned rolls, missed transfers, andcore loading errors. The rewinder 10 therefore will not have to shutdown whenever one or more of these problems occurs because the windingmodules 1-6 can be programmed to sense a problem and work around theparticular problem without shutting down. For instance, if a web breakproblem occurred, the rewinder 10 may perform a web cut by a cut-offmodule 60 and then initiate a new transfer sequence in order to start anew winding about the next available winding module 1-6. Any portion ofthe web 36 that was not wound would travel to the end of the webtransport apparatus 34 where a waste removal apparatus 200 could be usedto remove and transport the waste to a location remote from the rewinder10. The waste removal apparatus 200 could be for instance an airconveying system. The winding module 1-6 whose winding cycle wasinterrupted due to the web break could then be positioned accordinglyand initiate removal of the improperly formed rolled product 22.Subsequently, the winding module 1-6 could resume normal operation.During this entire time, the rewinder 10 would not have to shut down.

Another exemplary embodiment of the present invention involves the useof a slit web. Here, the web 36 is cut one or more times in the machinedirection and each slit section is routed to a plurality of windingmodules 12. It is therefore possible to wind the web 36 by two or moremodules 12 at the same time.

Exemplary embodiments of the present invention can allow for the windingprocess to be performed at the back end of a tissue machine. In thisway, the tissue web 36 could be directly converted to product sizedrolls 22 which in turn would bypass the need to first wind a parent rollduring the manufacturing and subsequent rewinding process. Still anotherexemplary embodiment of the present invention makes use of only a singlewinding module 12, instead of a plurality of winding modules 12.

The exemplary embodiment of the rewinder shown in FIG. 5 is one possibleconfiguration for the movement of the plurality of independent windingmodules 12. A positioning apparatus member 66 is present and is attachedto the frame 14. The positioning apparatus member 66 extends down to alocation proximate to the winding location of the web 36. The pluralityof independent winding modules 12 are slidably engaged with thepositioning apparatus member 66 so that the center, surface, orcenter/surface winding procedure can be accomplished. It is to beunderstood that alternative ways of mounting and sliding the pluralityof independent winding modules 12 in a vertical direction can beaccomplished by those skilled in the art. The plurality of independentwinding modules 12 of FIG. 5 are arranged in a substantially lineardirection. In addition, the web transport apparatus 34 is also linear inorientation at the location proximate to the plurality of independentwinding modules 12. The embodiments depicted are of an orientation ofthe web transport device in a substantially horizontal plane. However,it should be realized that any orientation other than horizontal couldbe utilized. Furthermore, the embodiments depicted utilize modules thatonly engage one side of the web transport apparatus. It should beunderstood that a winder could be configured where the winding modulesengage more than one side of the web transport apparatus.

FIG. 8 shows an alternative configuration of both the web transportapparatus 34 and the plurality of independent winding modules 12. Theexemplary embodiment shown in FIG. 8 is a plurality of winding modules12 that are radially disposed with respect to one another, and a webtransport apparatus 34 that is cylindrical in shape. The web transportapparatus 34 in this case can be, for instance, a vacuum roll. Each ofthe winding modules 1-6 are arranged about the web transport apparatus34 such that the winding modules 1-6 are moved towards and away from theweb transport apparatus 34 by the positioning apparatus 56.

The operation of the exemplary embodiment shown in FIG. 8 issubstantially similar to that as previously discussed. Winding module 1is shown in the process of loading a core 24. The mandrel 26 of windingmodule 1 has a distance from the center of the web transport apparatus34 designated as a core loading position 100. Winding module 3 is shownin the process of stripping a rolled product 22. The center of themandrel 26 of winding module 3 is located at a stripping position 102from the center of the web transport apparatus 34. Winding module 4 isshown in the process of engaging the web 36 and winding the web 36 ontothe core 24, that is loaded on the driven mandrel 26, to form a rolledproduct 22. A nip 68 is formed between the core 24, that is loaded onmandrel 26, and the web transport apparatus 34. The nip 68 is located ata winding position 104 at a distance from the center of the webtransport apparatus 34.

Winding modules 2 and 6 are located at the core loading position 100.However, these modules may be positioned such that maintenance can beperformed on them, or be in the “ready to wind” position. Module 5 is atthe stripping position 102. However, module 5 may also be in the processof just completing the stripping of a rolled product 22.

FIG. 9 discloses an exemplary embodiment of a winding module that isused in the configuration disclosed in FIG. 8. The winding module ofFIG. 9 is substantially the same as the winding module shown in FIG. 6,although configured for a circular array configuration as opposed to alinear array configuration.

The present disclosure may be better understood with reference to thefollowing example.

EXAMPLE 1

A winding system as shown in FIG. 1 and as described above was used toproduce various rolled tissue products. In particular, the rolledproducts comprised bath tissue. After the products were produced, theproducts were tested for various properties.

During the winding process, the torque of the mandrel, the nip pressure,and the web tension were controlled in order to vary the roll firmnessand the roll bulk. The following tests were conducted on the products:

Roll Bulk

Roll Bulk is the volume of paper divided by its mass on the wound roll.Roll Bulk is calculated by multiplying pi (3.142) by the quantityobtained by calculating the difference of the roll diameter squared incm squared (cm²) and the outer core diameter squared in cm squared (cm²)divided by 4 divided by the quantity sheet length in cm multiplied bythe sheet count multiplied by the bone dry Basis Weight of the sheet ingrams (g) per cm squared (cm²).

Roll Bulk in cc/g=3.142.times.(Roll Diameter squared in cm²-outer CoreDiameter squared in cm²)/(4.times.Sheet length in cm.times.sheetcount.times.Basis Weight in g/cm²) or Roll Bulk incc/g=0.785.times.(Roll Diameter squared in cm²-outer Core Diametersquared in cm²)/(Sheet length in cm.times.sheet count.times.Basis Weightin g/cm²).

Firmness

The Kershaw Test is a test used for determining roll firmness. TheKershaw Test is described in detail in U.S. Pat. No. 6,077,590 toArcher, et al., which is incorporated herein by reference. The apparatusis available from Kershaw Instrumentation, Inc., Swedesboro, N.J., andis known as a Model RDT-2002 Roll Density Tester. During the test, arolled product is placed on a spindle on a traverse table. The motion ofthe traverse table causes a sensing probe to make contact with the towelor bath tissue roll. The instant the sensing probe contacts the roll,the force exerted on the load cell will exceed the low set point of 6grams and the displacement display will be zeroed and begin indicatingthe penetration of the probe. When the force exerted on the sensingprobe exceeds the high set point of 687 grams, the value is recorded.After the value is recorded, the traverse table will stop and return tothe starting position. The displacement display indicates thedisplacement/penetration in millimeters. The tester will record thisreading. Next the tester will rotate the tissue or towel roll 90 degreeson the spindle and repeat the test. The roll firmness value is theaverage of the two readings. The test needs to be performed in acontrolled environment of 73.4.+−.1.8 degrees F. and 50.+−0.2% relativehumidity. The rolls to be tested need to be introduced to thisenvironment at least 4 hours before testing.

Tensile Strength, Geometric Mean Tensile Strength (GMT), and GeometricMean Tensile Energy Absorbed (GMTEA):

The tensile test that was performed used tissue samples that wereconditioned at 23.degree. C.+−.1.degree. C. and 50%.+−.2% relativehumidity for a minimum of 4 hours. The samples were cut into 3 inch widestrips in the machine direction (MD) and cross-machine direction (CD)using a precision sample cutter model JDC 15M-10, available fromThwing-Albert Instruments, a business having offices located inPhiladelphia, Pa., U.S.A.

The gauge length of the tensile frame was set to four inches. Thetensile frame was an Alliance RT/1 frame run with TestWorks 4 software.The tensile frame and the software are available from MTS SystemsCorporation, a business having offices located in Minneapolis, Minn.,U.S.A.

A 3″ strip was then placed in the jaws of the tensile frame andsubjected to a strain applied at a rate of 25.4 cm per minute until thepoint of sample failure. The stress on the tissue strip is monitored asa function of the strain. The calculated outputs included the peak load(grams-force/3″, measured in grams-force), the peak stretch (%,calculated by dividing the elongation of the sample by the originallength of the sample and multiplying by 100%), the % stretch@500grams-force, the tensile energy absorption (TEA) at break(grams-force*cm/cm.sup.2, calculated by integrating or taking the areaunder the stress-strain curve up the point of failure where the loadfalls to 30% of its peak value), and the slope A (kilograms-force,measured as the slope of the stress-strain curve from 57-150grams-force).

Each tissue code (minimum of five replicates) was tested in the machinedirection (MD) and cross-machine direction (CD). Geometric means of thetensile strength and tensile energy absorption (TEA) were calculated asthe square root of the product of the machine direction (MD) and thecross-machine direction (CD). This yielded an average value that isindependent of testing direction.

Elastic Modulus (Maximum Slope) and Geometric Mean Modulus (GMM) asMeasures of Sheet Stiffness:

Elastic Modulus (Maximum Slope) E(kg.sub.f) is the elastic modulusdetermined in the dry state and is expressed in units of kilograms offorce. TAPPI conditioned samples with a width of 3 inches are placed intensile tester jaws with a gauge length (span between jaws) of 4 inches.The jaws move apart at a crosshead speed of 25.4 cm/min and the slope istaken as the least squares fit of the data between stress values of 57grams of force and 150 grams of force. If the sample is too weak tosustain a stress of at least 200 grams of force without failure, anadditional ply is repeatedly added until the multi-ply sample canwithstand at least 200 grams of force without failure. The geometricmean modulus or geometric mean slope was calculated as the square rootof the product of the machine direction (MD) and the cross direction(CD) elastic moduli (maximum slopes), yielding an average value that isindependent of testing direction.

The following results were obtained. As shown below, roll bulk wasvaried between about 2 cc/g to about 14 cc/g.

TABLE 1 MD MD Roll Bulk Diameter Firmness BW Slope TEA Sample Productcc/g mm mm gsm MD MD % Kg-force J/m2 1 1 ply 14.089 108 9 26.69 135019.36 3499.77 13.358 2 1 ply 9.638 125 3.3 27.99 1435 12.92 12365.2714.152 3 1 ply 7.360   8″ 3 36.81 2870 18.41 15235.63 36.365 4 2 ply10.899 124 7.2 42.95 1542 11.96 7112.52 10.297 5 1 ply 5.071 124 3.124.43 1096 10.68 7808.83 7.053 6 1 ply 13.830 135 — 28.8 — — — — 7 1 ply5.632 108 — 28.8 — — — — 8 1 ply 6.132 112 — 28.8 — — — — 9 1 ply 8.112124 — 28.8 — — — — 10 1 ply 2.390 112 1 30.89 1632 14.15 17098.9 18.71911 2 ply 3.465  125.5 1 27.23 2091 11.27 18052.41 18.302

TABLE 2 CD Slope CD TEA GMT Caliper Sample Product CD CD % Kg-force J/m2Detach gf MD/CD mm 1 1 ply 824 6.81 10205.57 3.858 780 1055 1.638 0.41002 1 ply 712 5.91 10476.16 3.077 1002 1011 2.014 0.2540 3 1 ply 2014 10.88110.83 11.873 2016 2404 1.425 0.4953 4 2 ply 884 8.48 8134 5.071 15301167 1.745 0.5613 5 1 ply 511 6.44 8329.58 2.42 807 748 2.147 0.2870 6 1ply — — — — — — — 0.4250 7 1 ply — — — — — — — 0.2625 8 1 ply — — — — —— — 0.2625 9 1 ply — — — — — — — 0.2625 10 1 ply 794 4.91 15939.77 2.9061179 1138 2.055 0.1325 11 2 ply 690 5.68 17463.5 3.412 1590 1201 3.0330.1525

It should be understood that the invention includes variousmodifications that can be made to the exemplary embodiments of thecenter/surface rewinder/winder described herein as come within the scopeof the appended claims and their equivalents. Further, it is to beunderstood that the term “winder” as used in the claims is broad enoughto cover both a winder and a rewinder

What is claimed:
 1. A process for unwinding a parent roll into multipleproduct rolls comprising: unwinding a tissue web from a parent roll andconveying the tissue web downstream on a web transport apparatus at atension, the web transport apparatus having a first side and a secondopposite side, wherein a plurality of winding modules are positionedadjacent to the web transport apparatus, each winding module containinga mandrel extending across the web transport apparatus from the firstside to the second side, the mandrels being consecutively positioned andfixed along the web transport apparatus and in operative associationwith a driving device, wherein each of the plurality of winding modulesmay independently engage and disengage the tissue web moving downstreamwithout having to stop or slow the tissue web as it is conveyeddownstream; positioning a rotating mandrel adjacent to the transportapparatus for forming a nip between the web transport apparatus and themandrel, the driving device driving the mandrel at a speed and themandrel being positioned towards the transport apparatus at a nippressure; conveying the tissue web into the nip formed between themandrel and the web transport apparatus so as to initiate winding of theweb onto the mandrel; and controlling at least one of the nip pressure,the incoming tension and the torque of the mandrel in order to control aroll bulk of a roll being wound.
 2. A process as defined in claim 1,wherein the roll bulk is controlled by controlling at least two of thenip pressure, the incoming tension and the torque of the mandrel.
 3. Aprocess as defined in claim 2, wherein the plurality of winding modulesincludes at least three winding modules that are positioned adjacent tothe web transport apparatus and wherein during the process atsubstantially the same time, a core is located on a first mandrel of afirst winding module, a roll of material is formed on a second mandrelof a second winding module and a wound roll is stripped from a thirdmandrel of a third winding module.
 4. A process as defined in claim 3,wherein rolls are produced on the first mandrel having a first roll bulkand rolls are produced on the second mandrel having a second roll bulkand wherein the first roll bulk is different than the second roll bulk.5. A process as defined in claim 1, wherein the roll bulk of a rollbeing wound is controlled by controlling the nip pressure, the incomingtension and the torque of the mandrel.
 6. A process as defined in claim1, wherein the process is capable and configured to produce wound rollshaving a roll bulk of anywhere between about 3 cc/g to about 13 cc/gsolely by controlling at least one of the nip pressure, the incomingtension and the torque of the mandrel.
 7. A process as defined in claim6, further comprising the step of cutting the tissue web after a rolledproduct is formed on the mandrel and wherein the tissue web is cut at aweb tension of less than about 220 grams of force.
 8. A process asdefined in claim 1, wherein the process is capable and configured toproduce wound rolls having a roll bulk of anywhere between about 2 cc/gto about 14 cc/g solely by controlling at least one of the nip pressure,the incoming tension and the torque of the mandrel.
 9. A process asdefined in claim 1, wherein the roll bulk is increased by decreasing nippressure, decreasing incoming tension, or decreasing the torque of themandrel.
 10. A process as defined in claim 1, wherein the roll bulk isdecreased by increasing web tension, by increasing nip pressure, or byincreasing the torque of the mandrel.
 11. A process as defined in claim1, further comprising the step of cutting the tissue web as a rolledproduct is finishing being formed on the mandrel and wherein the tissueweb is cut at a web tension of less than about 220 grams of force basedon a sheet width of 10.6 cm.
 12. A process as defined in claim 11,further comprising the steps of: cutting the tissue web after a rolledproduct is formed on the mandrel; continuing to unwind the tissue webfrom the parent roll and conveying a leading edge of the tissue webdownstream on the web transport apparatus; and conveying the tissue webinto a nip formed between the web transport apparatus and a secondmandrel so as to initiate winding of the web on the second mandrel in acontinuous manner such that a speed of the web transport apparatusremains substantially constant.
 13. A process as defined in claim 1,further comprising the step of cutting the tissue web after a rolledproduct is formed on the mandrel and wherein the tissue web is cut at aweb tension of less than about 190 grams of force based on a sheet widthof 10.6 cm.
 14. A process as defined in claim 1, wherein the tissue webis conveyed on the web transport apparatus while being wound onto themandrel at an average speed of from about 1500 feet per minute to about3000 feet per minute.
 15. A process as defined in claim 1, wherein theroll bulk is controlled solely by varying nip pressure.
 16. A process asdefined in claim 1, further comprising the step of accelerating themandrel to a rotation speed that substantially matches the speed of theweb transport apparatus prior to forming the nip between the webtransport apparatus and the mandrel.
 17. A process as defined in claim1, further comprising the step of placing a core onto the mandrel priorto positioning the mandrel adjacent to the transport apparatus, thetissue web being wound upon the core.
 18. A process as defined in claim1, further comprising the steps of: loading a core on the mandrel;accelerating the mandrel to a desired rotation speed; positioning thewinding module to initiate contact between the rotating core and thetissue web; and stripping the rolled product from the winding module.19. A process as defined in claim 1, wherein winding on the mandrel iscarried out by using a combination of center winding and surfacewinding, center winding occurring by driving the mandrel and surfacewinding occurring by positioning the mandrel towards the web transportapparatus at a controllable magnitude to create the nip pressure.
 20. Aprocess as defined in claim 1, further comprising the steps of: cuttingthe tissue web after a rolled product is formed on the mandrel;continuing to unwind the tissue web from the parent roll and conveying aleading edge of the tissue web downstream on the web transportapparatus; and conveying the tissue web into a nip formed between theweb transport apparatus and a second mandrel so as to initiate windingof the web on the second mandrel in a continuous manner such that aspeed of the web transport apparatus remains substantially constant. 21.A process as defined in claim 1, wherein the transport apparatuscomprises a conveyor belt, the conveyor belt comprising a vacuumconveyor belt for holding the tissue web against the surface of theconveyor belt as the web is conveyed downstream.